Sinkhole Inspection, Safety Analyses, and Remedial Measures of Kayabelen Embankment Dam
Publication: Journal of Performance of Constructed Facilities
Volume 31, Issue 3
Abstract
The cause and mechanism of a sinkhole that has occurred on the downstream shoulder of a large embankment dam are studied. Since the downstream shoulder of the embankment was softened as a result of saturation, the slope safety of the embankment dam was reanalyzed by extending the saturation zone beyond the filter layers. Calculation results show that the dam is not safe currently in the area of the sinkhole section. The source of this problem was sought. Excavation of a trench at the sinkhole section was planned to take immediate action against failure. This trench excavation resulted in a fast, inexpensive, unambiguous, and effective way to rapidly identify the reason for the sinkhole. Trench excavation showed that the sinkhole problem was associated with the deterioration of the curved trace of the bottom outlet conduit: a rupture in a steel conduit at a poorly welded joint and a poor concrete section with a lack of reinforcement. High reservoir pressure through the rupture caused particle rearrangements, heave occurrence, upward propagation of cavities, and finally a sinkhole. In the study, remedial measures and the lessons learned from the case are also explained.
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References
ASWCC (Arkansas Soil and Water Conservation Commission). (2002). “Inspection and maintenance manual for owner inspection.” Little Rock, AR.
Foster, M., Fell, R., and Spannagle, M. (2000). “The statistics of embankment dam failures and accidents.” Can. Geotech. J., 37(5), 1000–1024.
Gutiérrez, F., Cooper, A. H., and Johnson, K. S. (2008). “Identification, prediction and mitigation of sinkhole hazards in evaporate karst areas.” Environ. Geol., 53(5), 1007–1022.
Sherard, J. L. (1972). “Piping in earth dams of dispersive clay.” Proc., Specialty Conf. on Performance of Earth and Earth-Supported Structures, ASCE, Reston, VA.
Sherard, J. L. (1977). “Discussion of ‘Load transfer and hydraulic fracturing in zoned dams,’ by F. H. Kulhawy and T. M. Gurtowsky.” J. Geotech. Eng. Div., 103(GT7), 831–833.
Sherard, J. L. (1979). “Sinkholes in dams of coarse, broadly graded soils.” Proc., 13th ICOLD Congress, India, Vol 2.
Sherard, J. L. (1985). “Hydraulic fracturing in embankment dams.” Proc., Symp. on Seepage and Leakage from Dams and Impoundments, Volpe R. L. and Kelly W. E., eds., ASCE, Reston, VA.
Siegel, R. A., and Bosscher, P. J. (1975). “A description of the use of STABL’s programmed solution for the general slope stability problem.” Purdue Univ., West Lafayette, IN.
State Hydraulic Works. (1993). “Kayabelen dam design.” Ankara, Turkey.
University of Wisconsin-Madison. (2009). WinStabl programmed solution for the general slope stability problem, Madison, WI.
USDIBR (U.S. Department of the Interior Bureau of Reclamation). (2007). Potential failure modes related to seepage and piping potential: A presentation on managing water in the West, Bureau of Reclamation, Washington, DC.
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©2016 American Society of Civil Engineers.
History
Received: Sep 29, 2015
Accepted: Aug 30, 2016
Published online: Nov 17, 2016
Discussion open until: Apr 17, 2017
Published in print: Jun 1, 2017
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